1-Aryl-1H- and 2-aryl-2H-1,2,3-triazole derivatives blockade P2X7 receptor in vitro and inflammatory response in vivo.

Fifty-one 1,2,3-triazole derivatives were synthesized and evaluated with respect to P2X7 receptor (P2X7R) activity and its associated pore. These triazoles were screened in vitro for dye uptake assay and its cytotoxicity against mammalian cell types. Seven 1,2,3-triazole derivatives (5e, 6e, 8h, 9d, 9i, 11, and 12) potently blocked P2X7 receptor pore formation in vitro (J774.G8 cells and peritoneal macrophages). All blockers displayed IC50 value inferior to 500 nM, and they have low toxicity in either cell types. These seven selected triazoles inhibited P2X7R mediated interleukin-1 (IL-1ß) release. In particular, compound 9d was the most potent P2X7R blocker. Additionally, in mouse acute models of inflammatory responses induced by ATP or carrageenan administration in the paw, compound 9d promoted a potent blocking response. Similarly, 9d also reduced mouse LPS-induced pleurisy cellularity. In silico predictions indicate this molecule appropriate to develop an anti-inflammatory agent when it was compared to commercial analogs. Electrophysiological studies suggest a competitive mechanism of action of 9d to block P2X7 receptor. Molecular docking was performed on the ATP binding site in order to observe the preferential interaction pose, indicating that binding mode of the 9d is by interacting its 1,2,3-triazole and ether moiety with positively charged residues and with its chlorobenzene moiety orientated toward the apolar end of the ATP binding site which are mainly composed by the Ile170, Trp167 and Leu309 residues from α subunit. These results highlight 9d derivative as a drug candidate with potential therapeutic application based on P2X7 receptor blockade.

P2X7 receptor as a novel drug delivery system to increase the entrance of hydrophilic drugs into cells during photodynamic therapy.

The second-generation photosensitizer methylene blue (MB) exhibits photochemical and photophysical properties suitable for photodynamic therapy (PDT)-based cancer treatment. However, the clinical application of MB is limited because of its high hydrophilicity, which hinders its penetration into tumor tissues. Therefore, new methods to improve the entry of MB into the cytoplasm of target cells are necessary. Because MB has a mass of 319 Da, transient pores on the plasma membrane, such as the pore induced by the P2X7 receptor (P2X7R) that allows the passage of molecules up to 900 Da, could be used. Using MTT viability assays, flow cytometry experiments, and fluorescence microscopy, we evaluated the toxicity and phototoxicity of MB and potentiation effects of ATP and MB on cell death processes in the J774 cell line (via a P2X7-associated pore). We observed that treatment with 5 µM MB for 15 min promoted the rate of entry of MB into the cytoplasm to 4.7 %. However, treatment with 5 µM MB and 1 mM ATP for the same amount of time increased this rate to 90.2 %. However, this effect was inhibited by pretreatment with a P2X7 antagonist. We used peritoneal macrophages and a cell line that does not express P2X7R as controls. These cells were more resistant to PDT with MB under the same experimental conditions. Taken together, these results suggest the use of the pore associated with P2X7R as a drug delivery system to increase the passage of hydrophilic drugs into cells that express this receptor, thus facilitating PDT.